From: Gereon Kremer Date: Thu, 24 Mar 2022 19:14:40 +0000 (+0100) Subject: Document arithmetic proof rules (#8373) X-Git-Tag: cvc5-1.0.0~185 X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=bedf02b659d238b438e1176694c3f7e44b9cdacc;p=cvc5.git Document arithmetic proof rules (#8373) This PR converts the documentation for the arithmetic proof rules, excluding those for transcendentals and coverings. --- diff --git a/src/proof/proof_rule.h b/src/proof/proof_rule.h index e7ef6d7c0..e4691d7f9 100644 --- a/src/proof/proof_rule.h +++ b/src/proof/proof_rule.h @@ -517,7 +517,8 @@ enum class PfRule : uint32_t * :cpp:enumerator:`RESOLUTION ` * - let :math:`C_1'` be equal, in its set representation, to :math:`C_1`, * - for each :math:`i > 1`, let :math:`C_i'` be equal, it its set - * representation, to :math:`C_{i-1} \diamond{L_{i-1},\mathit{pol}_{i-1}} C_i'` + * representation, to :math:`C_{i-1} \diamond{L_{i-1},\mathit{pol}_{i-1}} + * C_i'` * * The result of the chain resolution is :math:`C`, which is equal, in its set * representation, to :math:`C_n'` @@ -1475,114 +1476,154 @@ enum class PfRule : uint32_t // strings::InferProofCons::convert. STRING_INFERENCE, - //================================================= Arithmetic rules - // ======== Adding Inequalities - // Note: an ArithLiteral is a term of the form (>< poly const) - // where - // >< is >=, >, ==, <, <=, or not(== ...). - // poly is a polynomial - // const is a rational constant - - // Children: (P1:l1, ..., Pn:ln) - // where each li is an ArithLiteral - // not(= ...) is dis-allowed! - // - // Arguments: (k1, ..., kn), non-zero reals - // --------------------- - // Conclusion: (>< t1 t2) - // where >< is the fusion of the combination of the >< is always one of <, <= - // NB: this implies that lower bounds must have negative ki, - // and upper bounds must have positive ki. - // t1 is the sum of the scaled polynomials (k_1 * poly_1 + ... + k_n * - // poly_n) t2 is the sum of the scaled constants (k_1 * const_1 + ... + k_n - // * const_n) + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Adding inequalities** + * + * An arithmetic literal is a term of the form :math:`p \diamond c` where + * :math:`\diamond \in \{ <, \leq, =, \geq, > \}`, :math:`p` a + * polynomial and :math:`c` a rational constant. + * + * .. math:: + * \inferrule{l_1 \dots l_n \mid k_1 \dots k_n}{t_1 \diamond t_2} + * + * where :math:`k_i \in \mathbb{R}, k_i \neq 0`, :math:`\diamond` is the + * fusion of the :math:`\diamond_i` (flipping each if its :math:`k_i` is + * negative) such that :math:`\diamond_i \in \{ <, \leq \}` (this implies that + * lower bounds have negative :math:`k_i` and upper bounds have positive + * :math:`k_i`), :math:`t_1` is the sum of the scaled polynomials and + * :math:`t_2` is the sum of the scaled constants: + * + * .. math:: + * t_1 \colon= k_1 \cdot p_1 + \cdots + k_n \cdot p_n + * + * t_2 \colon= k_1 \cdot c_1 + \cdots + k_n \cdot c_n + * + * \endverbatim + */ MACRO_ARITH_SCALE_SUM_UB, - // ======== Sum Upper Bounds - // Children: (P1, ... , Pn) - // where each Pi has form (>< L R) - // where >< is < if any > i c)) - // where i has integer type. - // Arguments: none - // --------------------- - // Conclusion: (>= i leastIntGreaterThan(c)}) + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Tighten strict integer lower bounds** + * + * .. math:: + * \inferrule{i > c \mid -}{i \geq \lceil c \rceil} + * + * where :math:`i` has integer type. + * \endverbatim + */ INT_TIGHT_LB, - // ======== Trichotomy of the reals - // Children: (A B) - // Arguments: (C) - // --------------------- - // Conclusion: (C), - // where (not A) (not B) and C - // are (> x c) (< x c) and (= x c) - // in some order - // note that "not" here denotes arithmetic negation, flipping - // >= to <, etc. + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Trichotomy of the reals** + * + * .. math:: + * \inferrule{A, B \mid C}{C} + * + * where :math:`\neg A, \neg B, C` are :math:`x < c, x = c, x > c` in some order. + * Note that :math:`\neg` here denotes arithmetic negation, i.e., flipping :math:`\geq` to :math:`<` etc. + * \endverbatim + */ ARITH_TRICHOTOMY, - // ======== Arithmetic operator elimination - // Children: none - // Arguments: (t) - // --------------------- - // Conclusion: arith::OperatorElim::getAxiomFor(t) + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Operator elimination** + * + * .. math:: + * \inferrule{- \mid t}{\texttt{arith::OperatorElim::getAxiomFor(t)}} + * \endverbatim + */ ARITH_OP_ELIM_AXIOM, - // ======== Arithmetic polynomial normalization - // Children: none - // Arguments: ((= t s)) - // --------------------- - // Conclusion: (= t s) - // where arith::PolyNorm::isArithPolyNorm(t, s) = true + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Polynomial normalization** + * + * .. math:: + * \inferrule{- \mid t = s}{t = s} + * + * where :math:`\texttt{arith::PolyNorm::isArithPolyNorm(t, s)} = \top`. + * \endverbatim + */ ARITH_POLY_NORM, - //======== Multiplication sign inference - // Children: none - // Arguments: (f1, ..., fk, m) - // --------------------- - // Conclusion: (=> (and f1 ... fk) (~ m 0)) - // Where f1, ..., fk are variables compared to zero (less, greater or not - // equal), m is a monomial from these variables, and ~ is the comparison (less - // or greater) that results from the signs of the variables. All variables - // with even exponent in m should be given as not equal to zero while all - // variables with odd exponent in m should be given as less or greater than - // zero. + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Sign inference** + * + * .. math:: + * \inferrule{- \mid f_1 \dots f_k, m}{(f_1 \land \dots \land f_k) \rightarrow m \diamond 0} + * + * where :math:`f_1 \dots f_k` are variables compared to zero (less, greater + * or not equal), :math:`m` is a monomial from these variables and + * :math:`\diamond` is the comparison (less or equal) that results from the + * signs of the variables. All variables with even exponent in :math:`m` + * should be given as not equal to zero while all variables with odd exponent + * in :math:`m` should be given as less or greater than zero. + * \endverbatim + */ ARITH_MULT_SIGN, - //======== Multiplication with positive factor - // Children: none - // Arguments: (m, (rel lhs rhs)) - // --------------------- - // Conclusion: (=> (and (> m 0) (rel lhs rhs)) (rel (* m lhs) (* m rhs))) - // Where rel is a relation symbol. + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Multiplication with positive factor** + * + * .. math:: + * \inferrule{- \mid m, l \diamond r}{(m > 0 \land l \diamond r) \rightarrow m \cdot l \diamond m \cdot r} + * + * where :math:`\diamond` is a relation symbol. + * \endverbatim + */ ARITH_MULT_POS, - //======== Multiplication with negative factor - // Children: none - // Arguments: (m, (rel lhs rhs)) - // --------------------- - // Conclusion: (=> (and (< m 0) (rel lhs rhs)) (rel_inv (* m lhs) (* m rhs))) - // Where rel is a relation symbol and rel_inv the inverted relation symbol. + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Multiplication with negative factor** + * + * .. math:: + * \inferrule{- \mid m, l \diamond r}{(m < 0 \land l \diamond r) \rightarrow m \cdot l \diamond_{inv} m \cdot r} + * + * where :math:`\diamond` is a relation symbol and :math:`\diamond_{inv}` the + * inverted relation symbol. + * \endverbatim + */ ARITH_MULT_NEG, - //======== Multiplication tangent plane - // Children: none - // Arguments: (t, x, y, a, b, sgn) - // --------------------- - // Conclusion: - // sgn=-1: (= (<= t tplane) (or (and (<= x a) (>= y b)) (and (>= x a) (<= y - // b))) sgn= 1: (= (>= t tplane) (or (and (<= x a) (<= y b)) (and (>= x a) - // (>= y b))) - // Where x,y are real terms (variables or extended terms), t = (* x y) - // (possibly under rewriting), a,b are real constants, and sgn is either -1 - // or 1. tplane is the tangent plane of x*y at (a,b): b*x + a*y - a*b + /** + * \verbatim embed:rst:leading-asterisk + * **Arithmetic -- Multiplication tangent plane** + * + * .. math:: + * \inferruleSC{- \mid t, x, y, a, b, \sigma}{(t \leq tplane) \leftrightarrow ((x \leq a \land y \geq b) \lor (x \geq a \land y \leq b))}{if $\sigma = -1$} + * + * \inferruleSC{- \mid t, x, y, a, b, \sigma}{(t \geq tplane) \leftrightarrow ((x \leq a \land y \leq b) \lor (x \geq a \land y \geq b))}{if $\sigma = 1$} + * + * where :math:`x,y` are real terms (variables or extended terms), + * :math:`t = x \cdot y` (possibly under rewriting), :math:`a,b` are real + * constants, :math:`\sigma \in \{ 1, -1\}` and :math:`tplane := b \cdot x + a \cdot y - a \cdot b` is the tangent plane of :math:`x \cdot y` at :math:`(a,b)`. + * \endverbatim + */ ARITH_MULT_TANGENT, /**